无脊椎动物与细菌之间的模型关联揭示了互惠关系的共同趋势。
Common trends in mutualism revealed by model associations between invertebrates and bacteria.
机构信息
Department of Bacteriology, University of Wisconsin-Madison, Madison, WI 53706, USA.
出版信息
FEMS Microbiol Rev. 2010 Jan;34(1):41-58. doi: 10.1111/j.1574-6976.2009.00193.x.
Abstract
Mutually beneficial interactions between microorganisms and animals are a conserved and ubiquitous feature of biotic systems. In many instances animals, including humans, are dependent on their microbial associates for nutrition, defense, or development. To maintain these vital relationships, animals have evolved processes that ensure faithful transmission of specific microbial symbionts between generations. Elucidating mechanisms of transmission and symbiont specificity has been aided by the study of experimentally tractable invertebrate animals with diverse and highly evolved associations with microorganisms. Here, we review several invertebrate model systems that contribute to our current understanding of symbiont transmission, recognition, and specificity. Although the details of transmission and symbiont selection vary among associations, comparisons of diverse mutualistic associations are revealing a number of common themes, including restriction of symbiont diversity during transmission and glycan-lectin interactions during partner selection and recruitment.
摘要
微生物和动物之间互利的相互作用是生物系统的一个保守和普遍的特征。在许多情况下,动物,包括人类,依赖于它们的微生物伙伴来获得营养、防御或发育。为了维持这些至关重要的关系,动物已经进化出了一些过程,以确保特定的微生物共生体在代际之间的忠实传递。通过研究具有多样化和高度进化的微生物关联的实验上可处理的无脊椎动物,阐明了传递机制和共生体特异性,这一过程得到了促进。在这里,我们回顾了几个无脊椎动物模型系统,这些系统有助于我们目前对共生体传递、识别和特异性的理解。尽管在不同的关联中传递和共生体选择的细节有所不同,但对不同的互利关联的比较揭示了一些共同的主题,包括在传递过程中限制共生体的多样性,以及在伙伴选择和招募过程中糖-凝集素相互作用。
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